/*
 * 86Box    A hypervisor and IBM PC system emulator that specializes in
 *          running old operating systems and software designed for IBM
 *          PC systems and compatibles from 1981 through fairly recent
 *          system designs based on the PCI bus.
 *
 *          This file is part of the 86Box distribution.
 *
 *          Implementation of the IBM PS/2 SCSI controller with
 *          cache for MCA only.
 *
 *
 *
 * Authors: Sarah Walker, <https://pcem-emulator.co.uk/>
 *          TheCollector1995, <mariogplayer@gmail.com>
 *
 *          Copyright 2020 Sarah Walker.
 *          Copyright 2020 TheCollector1995.
 */
#include <inttypes.h>
#include <stdio.h>
#include <stdint.h>
#include <string.h>
#include <stdlib.h>
#include <stdarg.h>
#include <wchar.h>
#define HAVE_STDARG_H
#include <86box/86box.h>
#include <86box/io.h>
#include <86box/timer.h>
#include <86box/dma.h>
#include <86box/pic.h>
#include <86box/mca.h>
#include <86box/mem.h>
#include <86box/rom.h>
#include <86box/device.h>
#include <86box/nvr.h>
#include <86box/plat.h>
#include <86box/scsi.h>
#include <86box/scsi_device.h>
#include <86box/scsi_spock.h>

#define SPOCK_U68_1990_ROM "roms/scsi/ibm/64f4376.bin"
#define SPOCK_U69_1990_ROM "roms/scsi/ibm/64f4377.bin"

#define SPOCK_U68_1991_ROM "roms/scsi/ibm/92F2244.U68"
#define SPOCK_U69_1991_ROM "roms/scsi/ibm/92F2245.U69"

#define SPOCK_TIME         (20)

typedef enum {
    SCSI_STATE_IDLE,
    SCSI_STATE_SELECT,
    SCSI_STATE_SEND_COMMAND,
    SCSI_STATE_END_PHASE
} scsi_state_t;

#pragma pack(push, 1)
typedef struct {
    uint16_t pos;
    uint16_t pos1;
    uint16_t pos2;
    uint16_t pos3;
    uint16_t pos4;
    uint16_t pos5;
    uint16_t pos6;
    uint16_t pos7;
    uint16_t pos8;
} get_pos_info_t;

typedef struct {
    uint16_t scb_status;
    uint16_t retry_count;
    uint32_t residual_byte_count;
    uint32_t sg_list_element_addr;
    uint16_t device_dep_status_len;
    uint16_t cmd_status;
    uint16_t error;
    uint16_t reserved;
    uint16_t cache_info_status;
    uint32_t scb_addr;
} get_complete_stat_t;

typedef struct {
    uint32_t sys_buf_addr;
    uint32_t sys_buf_byte_count;
} SGE;

typedef struct {
    uint16_t command;
    uint16_t enable;
    uint32_t lba_addr;
    SGE      sge;
    uint32_t term_status_block_addr;
    uint32_t scb_chain_addr;
    uint16_t block_count;
    uint16_t block_length;
} scb_t;
#pragma pack(pop)

typedef struct {
    rom_t bios_rom;

    int bios_ver;
    int irq, irq_inactive;

    uint8_t pos_regs[8];

    uint8_t  basic_ctrl;
    uint32_t command;

    uint8_t attention,
        attention_pending;
    int attention_wait;

    uint8_t cir[4],
        cir_pending[4];

    uint8_t irq_status;

    uint32_t scb_addr;

    uint8_t status;

    get_complete_stat_t get_complete_stat;
    get_pos_info_t      get_pos_info;

    scb_t scb;
    int   scb_id;
    int   adapter_id;
    int   assign;
    int   present[8];

    int cmd_status;
    int cir_status;

    uint8_t pacing;
    uint8_t irq_state;
    uint8_t buf[0x600];

    struct {
        int phys_id;
        int lun_id;
    } dev_id[SCSI_ID_MAX];

    uint8_t  last_status, bus;
    uint8_t  cdb[12];
    int      cdb_len;
    int      cdb_id;
    uint32_t data_ptr, data_len;
    uint8_t  temp_cdb[12];

    int irq_requests[SCSI_ID_MAX];

    pc_timer_t callback_timer;

    int cmd_timer;

    int scb_state;
    int in_reset;
    int in_invalid;
    int spock_16bit;

    uint64_t temp_period;
    double   media_period;

    scsi_state_t scsi_state;
} spock_t;

#define CTRL_RESET                  (1 << 7)
#define CTRL_DMA_ENA                (1 << 1)
#define CTRL_IRQ_ENA                (1 << 0)

#define STATUS_CMD_FULL             (1 << 3)
#define STATUS_CMD_EMPTY            (1 << 2)
#define STATUS_IRQ                  (1 << 1)
#define STATUS_BUSY                 (1 << 0)

#define ENABLE_PT                   (1 << 12)

#define CMD_MASK                    0xff3f
#define CMD_ASSIGN                  0x040e
#define CMD_DEVICE_INQUIRY          0x1c0b
#define CMD_DMA_PACING_CONTROL      0x040d
#define CMD_FEATURE_CONTROL         0x040c
#define CMD_GET_POS_INFO            0x1c0a
#define CMD_INVALID_412             0x0412
#define CMD_GET_COMPLETE_STATUS     0x1c07
#define CMD_FORMAT_UNIT             0x1c16
#define CMD_READ_DATA               0x1c01
#define CMD_READ_DEVICE_CAPACITY    0x1c09
#define CMD_REQUEST_SENSE           0x1c08
#define CMD_RESET                   0x0400
#define CMD_SEND_OTHER_SCSI         0x241f
#define CMD_UNKNOWN_1C10            0x1c10
#define CMD_UNKNOWN_1C11            0x1c11
#define CMD_WRITE_DATA              0x1c02
#define CMD_VERIFY                  0x1c03

#define IRQ_TYPE_NONE               0x0
#define IRQ_TYPE_SCB_COMPLETE       0x1
#define IRQ_TYPE_SCB_COMPLETE_RETRY 0x5
#define IRQ_TYPE_ADAPTER_HW_FAILURE 0x7
#define IRQ_TYPE_IMM_CMD_COMPLETE   0xa
#define IRQ_TYPE_COMMAND_FAIL       0xc
#define IRQ_TYPE_COMMAND_ERROR      0xe
#define IRQ_TYPE_SW_SEQ_ERROR       0xf
#define IRQ_TYPE_RESET_COMPLETE     0x10

#ifdef ENABLE_SPOCK_LOG
int spock_do_log = ENABLE_SPOCK_LOG;

static void
spock_log(const char *fmt, ...)
{
    va_list ap;

    if (spock_do_log) {
        va_start(ap, fmt);
        pclog_ex(fmt, ap);
        va_end(ap);
    }
}
#else
#    define spock_log(fmt, ...)
#endif

static void
spock_rethink_irqs(spock_t *scsi)
{
    int irq_pending = 0;

    if (!scsi->irq_status) {
        for (uint8_t c = 0; c < SCSI_ID_MAX; c++) {
            if (scsi->irq_requests[c] != IRQ_TYPE_NONE) {
                /* Found IRQ */
                scsi->irq_status = c | (scsi->irq_requests[c] << 4);
                spock_log("Found IRQ: status = %02x\n", scsi->irq_status);
                scsi->status |= STATUS_IRQ;
                irq_pending = 1;
                break;
            }
        }
    } else
        irq_pending = 1;

    if (scsi->basic_ctrl & CTRL_IRQ_ENA) {
        if (irq_pending) {
            spock_log("IRQ issued\n");
            scsi->irq_inactive = 0;
            picint(1 << scsi->irq);
        } else {
            /* No IRQs pending, clear IRQ state */
            spock_log("IRQ cleared\n");
            scsi->irq_status   = 0;
            scsi->irq_inactive = 1;
            scsi->status &= ~STATUS_IRQ;
            picintc(1 << scsi->irq);
        }
    } else {
        spock_log("IRQ disabled\n");
        picintc(1 << scsi->irq);
    }
}

static __inline void
spock_set_irq(spock_t *scsi, int id, int type)
{
    spock_log("spock_set_irq id=%i type=%x %02x\n", id, type, scsi->irq_status);
    scsi->irq_requests[id] = type;
    if (!scsi->irq_status) /* Don't change IRQ status if one is currently being processed */
        spock_rethink_irqs(scsi);
}

static __inline void
spock_clear_irq(spock_t *scsi, int id)
{
    spock_log("spock_clear_irq id=%i\n", id);
    scsi->irq_requests[id] = IRQ_TYPE_NONE;
    spock_rethink_irqs(scsi);
}

static void
spock_add_to_period(spock_t *scsi, int TransferLength)
{
    scsi->temp_period += (uint64_t) TransferLength;
}

static void
spock_write(uint16_t port, uint8_t val, void *priv)
{
    spock_t *scsi = (spock_t *) priv;

    spock_log("spock_write: port=%04x val=%02x %04x:%04x\n", port, val, CS, cpu_state.pc);

    switch (port & 7) {
        case 0:
        case 1:
        case 2:
        case 3: /*Command Interface Register*/
            scsi->cir_pending[port & 3] = val;
            if (port & 2)
                scsi->cir_status |= 2;
            else
                scsi->cir_status |= 1;
            break;

        case 4: /*Attention Register*/
            scsi->attention_pending = val;
            scsi->attention_wait    = 2;
            scsi->status |= STATUS_BUSY;
            break;

        case 5: /*Basic Control Register*/
            if ((scsi->basic_ctrl & CTRL_RESET) && !(val & CTRL_RESET)) {
                spock_log("Spock: SCSI reset and busy\n");
                scsi->in_reset  = 1;
                scsi->cmd_timer = SPOCK_TIME * 2;
                scsi->status |= STATUS_BUSY;
            }
            scsi->basic_ctrl = val;
            spock_rethink_irqs(scsi);
            break;

        default:
            break;
    }
}

static void
spock_writew(uint16_t port, uint16_t val, void *priv)
{
    spock_t *scsi = (spock_t *) priv;

    switch (port & 7) {
        case 0: /*Command Interface Register*/
            scsi->cir_pending[0] = val & 0xff;
            scsi->cir_pending[1] = val >> 8;
            scsi->cir_status |= 1;
            break;
        case 2: /*Command Interface Register*/
            scsi->cir_pending[2] = val & 0xff;
            scsi->cir_pending[3] = val >> 8;
            scsi->cir_status |= 2;
            break;

        default:
            break;
    }

    spock_log("spock_writew: port=%04x val=%04x\n", port, val);
}

static uint8_t
spock_read(uint16_t port, void *priv)
{
    const spock_t *scsi = (spock_t *) priv;
    uint8_t  temp = 0xff;

    switch (port & 7) {
        case 0:
        case 1:
        case 2:
        case 3: /*Command Interface Register*/
            temp = scsi->cir_pending[port & 3];
            break;

        case 4: /*Attention Register*/
            temp = scsi->attention_pending;
            break;
        case 5: /*Basic Control Register*/
            temp = scsi->basic_ctrl;
            break;
        case 6: /*IRQ status*/
            temp = scsi->irq_status;
            break;
        case 7: /*Basic Status Register*/
            temp = scsi->status;
            spock_log("Cir Status=%d\n", scsi->cir_status);
            if (scsi->cir_status == 0) {
                spock_log("Status Cmd Empty\n");
                temp |= STATUS_CMD_EMPTY;
            } else if (scsi->cir_status == 3) {
                spock_log("Status Cmd Full\n");
                temp |= STATUS_CMD_FULL;
            }
            break;

        default:
            break;
    }

    spock_log("spock_read: port=%04x val=%02x %04x(%05x):%04x.\n", port, temp, CS, cs, cpu_state.pc);
    return temp;
}

static uint16_t
spock_readw(uint16_t port, void *priv)
{
    const spock_t *scsi = (spock_t *) priv;
    uint16_t       temp = 0xffff;

    switch (port & 7) {
        case 0: /*Command Interface Register*/
            temp = scsi->cir_pending[0] | (scsi->cir_pending[1] << 8);
            break;
        case 2: /*Command Interface Register*/
            temp = scsi->cir_pending[2] | (scsi->cir_pending[3] << 8);
            break;

        default:
            break;
    }

    spock_log("spock_readw: port=%04x val=%04x\n", port, temp);
    return temp;
}

static void
spock_rd_sge(spock_t *scsi, uint32_t Address, SGE *SG)
{
    dma_bm_read(Address, (uint8_t *) SG, sizeof(SGE), 2);
    spock_add_to_period(scsi, sizeof(SGE));
}

static int
spock_get_len(spock_t *scsi, scb_t *scb)
{
    uint32_t DataToTransfer = 0;

    spock_log("Data Buffer write: length %d, pointer 0x%04X\n",
              scsi->data_len, scsi->data_ptr);

    if (!scsi->data_len)
        return 0;

    if (scb->enable & ENABLE_PT) {
        for (uint32_t i = 0; i < scsi->data_len; i += 8) {
            spock_rd_sge(scsi, scsi->data_ptr + i, &scb->sge);

            DataToTransfer += scb->sge.sys_buf_byte_count;
        }
        return DataToTransfer;
    } else {
        return (scsi->data_len);
    }
}

static void
spock_process_imm_cmd(spock_t *scsi)
{
    int i;
    int j = 0;
    int adapter_id;
    int phys_id;
    int lun_id;

    scsi->assign = 0;

    switch (scsi->command & CMD_MASK) {
        case CMD_ASSIGN:
            scsi->assign = 1;
            adapter_id   = (scsi->command >> 16) & 15;
            phys_id      = (scsi->command >> 20) & 7;
            lun_id       = (scsi->command >> 24) & 7;
            if (adapter_id == 15) {
                if (phys_id == 7) /*Device 15 always adapter*/
                    spock_set_irq(scsi, scsi->attention & 0x0f, IRQ_TYPE_IMM_CMD_COMPLETE);
                else /*Can not re-assign device 15 (always adapter)*/
                    spock_set_irq(scsi, scsi->attention & 0x0f, IRQ_TYPE_COMMAND_FAIL);
            } else {
                if (scsi->command & (1 << 23)) {
                    spock_log("Assign: adapter id=%d\n", adapter_id);
                    scsi->dev_id[adapter_id].phys_id = -1;
                    spock_set_irq(scsi, scsi->attention & 0x0f, IRQ_TYPE_IMM_CMD_COMPLETE);
                } else {
                    if (phys_id != scsi->adapter_id) {
                        scsi->dev_id[adapter_id].phys_id = phys_id;
                        scsi->dev_id[adapter_id].lun_id  = lun_id;
                        spock_log("Assign: adapter dev=%x scsi ID=%i LUN=%i.\n", adapter_id, scsi->dev_id[adapter_id].phys_id, scsi->dev_id[adapter_id].lun_id);
                        spock_set_irq(scsi, scsi->attention & 0x0f, IRQ_TYPE_IMM_CMD_COMPLETE);
                    } else { /*Can not assign adapter*/
                        spock_log("Assign: PUN=%d, cannot assign adapter.\n", phys_id);
                        spock_set_irq(scsi, scsi->attention & 0x0f, IRQ_TYPE_COMMAND_FAIL);
                    }
                }
            }
            break;
        case CMD_DMA_PACING_CONTROL:
            scsi->pacing = scsi->cir[2];
            spock_log("Pacing control: %i\n", scsi->pacing);
            spock_set_irq(scsi, scsi->attention & 0x0f, IRQ_TYPE_IMM_CMD_COMPLETE);
            break;
        case CMD_FEATURE_CONTROL:
            spock_log("Feature control: timeout=%is d-rate=%i\n", (scsi->command >> 16) & 0x1fff, scsi->command >> 29);
            spock_set_irq(scsi, scsi->attention & 0x0f, IRQ_TYPE_IMM_CMD_COMPLETE);
            break;
        case CMD_INVALID_412:
            spock_log("Invalid 412\n");
            spock_set_irq(scsi, scsi->attention & 0x0f, IRQ_TYPE_IMM_CMD_COMPLETE);
            break;
        case CMD_RESET:
            spock_log("Reset Command, attention = %d.\n", scsi->attention & 0x0f);
            if ((scsi->attention & 0x0f) == 0x0f) { /*Adapter reset*/
                for (i = 0; i < 8; i++) {
                    scsi_device_reset(&scsi_devices[scsi->bus][i]);
                }

                for (i = 6; i > -1; i--) {
                    if (scsi_device_present(&scsi_devices[scsi->bus][i])) {
                        spock_log("Adapter Reset, SCSI reset present devices=%d, phys ID=%d, type=%04x.\n", j, scsi->dev_id[i].phys_id, scsi_devices[scsi->bus][i].type);
                        scsi->present[j] = i;
                        j++;
                    } else {
                        spock_log("Adapter Reset, SCSI reset not present devices=%d, phys ID=%d, type=%04x.\n", j, scsi->dev_id[i].phys_id, scsi_devices[scsi->bus][i].type);
                    }
                }

                scsi->scb_state = 0;
            }

            spock_set_irq(scsi, scsi->attention & 0x0f, IRQ_TYPE_IMM_CMD_COMPLETE);
            break;

        default:
            fatal("scsi_callback: Bad command %02x\n", scsi->command);
            break;
    }
}

static void
spock_execute_cmd(spock_t *scsi, scb_t *scb)
{
    int c;
    int j = 0;
    int old_scb_state;

    if (scsi->in_reset) {
        spock_log("Reset type = %d\n", scsi->in_reset);

        scsi->status &= ~STATUS_BUSY;
        scsi->irq_status = 0;

        for (c = 0; c < SCSI_ID_MAX; c++)
            spock_clear_irq(scsi, c);

        if (scsi->in_reset == 1) {
            scsi->basic_ctrl |= CTRL_IRQ_ENA;
        }

        spock_set_irq(scsi, 0x0f, IRQ_TYPE_RESET_COMPLETE);

        /*Reset device mappings*/
        for (c = 0; c < 7; c++) {
            scsi->dev_id[c].phys_id = c;
            scsi->dev_id[c].lun_id  = 0;
        }
        for (; c < (SCSI_ID_MAX - 1); c++)
            scsi->dev_id[c].phys_id = -1;

        scsi->in_reset = 0;

        for (c = 6; c > -1; c--) {
            if (scsi_device_present(&scsi_devices[scsi->bus][c])) {
                spock_log("Reset, SCSI reset present devices=%d, phys ID=%d, type=%04x.\n", j, scsi->dev_id[c].phys_id, scsi_devices[scsi->bus][c].type);
                scsi->present[j] = c;
                j++;
            } else {
                spock_log("Reset, SCSI reset not present devices=%d, phys ID=%d, type=%04x.\n", j, scsi->dev_id[c].phys_id, scsi_devices[scsi->bus][c].type);
            }
        }
        return;
    }

    if (scsi->in_invalid) {
        spock_log("Invalid command\n");
        spock_set_irq(scsi, scsi->attention & 0x0f, IRQ_TYPE_COMMAND_ERROR);
        scsi->in_invalid = 0;
        return;
    }

    spock_log("SCB State = %d\n", scsi->scb_state);

    do {
        old_scb_state = scsi->scb_state;

        switch (scsi->scb_state) {
            case 0: /* Idle */
                break;

            case 1: /* Select */
                if (scsi->dev_id[scsi->scb_id].phys_id == -1) {
                    uint16_t term_stat_block_addr7 = (0xe << 8) | 0;
                    uint16_t term_stat_block_addr8 = (0xa << 8) | 0;

                    spock_log("Start failed, SCB ID = %d\n", scsi->scb_id);
                    spock_set_irq(scsi, scsi->scb_id, IRQ_TYPE_COMMAND_FAIL);
                    scsi->scb_state = 0;
                    dma_bm_write(scb->term_status_block_addr + 0x7 * 2, (uint8_t *) &term_stat_block_addr7, 2, 2);
                    dma_bm_write(scb->term_status_block_addr + 0x8 * 2, (uint8_t *) &term_stat_block_addr8, 2, 2);
                    break;
                }

                dma_bm_read(scsi->scb_addr, (uint8_t *) &scb->command, 2, 2);
                dma_bm_read(scsi->scb_addr + 2, (uint8_t *) &scb->enable, 2, 2);
                dma_bm_read(scsi->scb_addr + 4, (uint8_t *) &scb->lba_addr, 4, 2);
                dma_bm_read(scsi->scb_addr + 8, (uint8_t *) &scb->sge.sys_buf_addr, 4, 2);
                dma_bm_read(scsi->scb_addr + 12, (uint8_t *) &scb->sge.sys_buf_byte_count, 4, 2);
                dma_bm_read(scsi->scb_addr + 16, (uint8_t *) &scb->term_status_block_addr, 4, 2);
                dma_bm_read(scsi->scb_addr + 20, (uint8_t *) &scb->scb_chain_addr, 4, 2);
                dma_bm_read(scsi->scb_addr + 24, (uint8_t *) &scb->block_count, 2, 2);
                dma_bm_read(scsi->scb_addr + 26, (uint8_t *) &scb->block_length, 2, 2);

                spock_log("SCB : \n"
                          "  Command = %04x\n"
                          "  Enable = %04x\n"
                          "  LBA addr = %08x\n"
                          "  System buffer addr = %08x\n"
                          "  System buffer byte count = %08x\n"
                          "  Terminate status block addr = %08x\n"
                          "  SCB chain address = %08x\n"
                          "  Block count = %04x\n"
                          "  Block length = %04x\n"
                          "  SCB id = %d, Phys id = %d, Spock CMD = %08x, CMD Mask = %02x.\n",
                          scb->command, scb->enable, scb->lba_addr,
                          scb->sge.sys_buf_addr, scb->sge.sys_buf_byte_count,
                          scb->term_status_block_addr, scb->scb_chain_addr,
                          scb->block_count, scb->block_length, scsi->scb_id, scsi->dev_id[scsi->scb_id].phys_id, scsi->command, scb->command & 0xc0);

                switch (scb->command & CMD_MASK) {
                    case CMD_GET_COMPLETE_STATUS:
                        {
                            spock_log("Get Complete Status\n");
                            get_complete_stat_t *get_complete_stat = &scsi->get_complete_stat;

                            get_complete_stat->scb_status            = 0x201;
                            get_complete_stat->retry_count           = 0;
                            get_complete_stat->residual_byte_count   = 0;
                            get_complete_stat->sg_list_element_addr  = 0;
                            get_complete_stat->device_dep_status_len = 0x0c;
                            get_complete_stat->cmd_status            = scsi->cmd_status << 8;
                            get_complete_stat->error                 = 0;
                            get_complete_stat->reserved              = 0;
                            get_complete_stat->cache_info_status     = 0;
                            get_complete_stat->scb_addr              = scsi->scb_addr;

                            dma_bm_write(scb->sge.sys_buf_addr, (uint8_t *) &get_complete_stat->scb_status, 2, 2);
                            dma_bm_write(scb->sge.sys_buf_addr + 2, (uint8_t *) &get_complete_stat->retry_count, 2, 2);
                            dma_bm_write(scb->sge.sys_buf_addr + 4, (uint8_t *) &get_complete_stat->residual_byte_count, 4, 2);
                            dma_bm_write(scb->sge.sys_buf_addr + 8, (uint8_t *) &get_complete_stat->sg_list_element_addr, 4, 2);
                            dma_bm_write(scb->sge.sys_buf_addr + 12, (uint8_t *) &get_complete_stat->device_dep_status_len, 2, 2);
                            dma_bm_write(scb->sge.sys_buf_addr + 14, (uint8_t *) &get_complete_stat->cmd_status, 2, 2);
                            dma_bm_write(scb->sge.sys_buf_addr + 16, (uint8_t *) &get_complete_stat->error, 2, 2);
                            dma_bm_write(scb->sge.sys_buf_addr + 18, (uint8_t *) &get_complete_stat->reserved, 2, 2);
                            dma_bm_write(scb->sge.sys_buf_addr + 20, (uint8_t *) &get_complete_stat->cache_info_status, 2, 2);
                            dma_bm_write(scb->sge.sys_buf_addr + 22, (uint8_t *) &get_complete_stat->scb_addr, 4, 2);
                            scsi->scb_state = 3;
                        }
                        break;

                    case CMD_UNKNOWN_1C10:
                        spock_log("Unknown 1C10\n");
                        dma_bm_read(scb->sge.sys_buf_addr, scsi->buf, scb->sge.sys_buf_byte_count, 2);
                        scsi->scb_state = 3;
                        break;

                    case CMD_UNKNOWN_1C11:
                        spock_log("Unknown 1C11\n");
                        dma_bm_write(scb->sge.sys_buf_addr, scsi->buf, scb->sge.sys_buf_byte_count, 2);
                        scsi->scb_state = 3;
                        break;

                    case CMD_GET_POS_INFO:
                        {
                            spock_log("Get POS Info\n");
                            get_pos_info_t *get_pos_info = &scsi->get_pos_info;

                            get_pos_info->pos  = scsi->spock_16bit ? 0x8efe : 0x8eff;
                            get_pos_info->pos1 = scsi->pos_regs[3] | (scsi->pos_regs[2] << 8);
                            get_pos_info->pos2 = scsi->irq | (scsi->pos_regs[4] << 8);
                            get_pos_info->pos3 = 1 << 12;
                            get_pos_info->pos4 = (7 << 8) | 8;
                            get_pos_info->pos5 = (16 << 8) | scsi->pacing;
                            get_pos_info->pos6 = (30 << 8) | 1;
                            get_pos_info->pos7 = 0;
                            get_pos_info->pos8 = 0;

                            dma_bm_write(scb->sge.sys_buf_addr, (uint8_t *) &get_pos_info->pos, 2, 2);
                            dma_bm_write(scb->sge.sys_buf_addr + 2, (uint8_t *) &get_pos_info->pos1, 2, 2);
                            dma_bm_write(scb->sge.sys_buf_addr + 4, (uint8_t *) &get_pos_info->pos2, 2, 2);
                            dma_bm_write(scb->sge.sys_buf_addr + 6, (uint8_t *) &get_pos_info->pos3, 2, 2);
                            dma_bm_write(scb->sge.sys_buf_addr + 8, (uint8_t *) &get_pos_info->pos4, 2, 2);
                            dma_bm_write(scb->sge.sys_buf_addr + 10, (uint8_t *) &get_pos_info->pos5, 2, 2);
                            dma_bm_write(scb->sge.sys_buf_addr + 12, (uint8_t *) &get_pos_info->pos6, 2, 2);
                            dma_bm_write(scb->sge.sys_buf_addr + 14, (uint8_t *) &get_pos_info->pos7, 2, 2);
                            dma_bm_write(scb->sge.sys_buf_addr + 16, (uint8_t *) &get_pos_info->pos8, 2, 2);
                            scsi->scb_state = 3;
                        }
                        break;

                    case CMD_DEVICE_INQUIRY:
                        scsi->cdb_id = scsi->assign ? scsi->dev_id[scsi->scb_id].phys_id : scsi->present[scsi->scb_id];
                        spock_log("Device Inquiry, ID=%d\n", scsi->cdb_id);
                        scsi->cdb[0]     = GPCMD_INQUIRY;
                        scsi->cdb[1]     = scsi->dev_id[scsi->scb_id].lun_id << 5; /*LUN*/
                        scsi->cdb[2]     = 0;                                      /*Page code*/
                        scsi->cdb[3]     = 0;
                        scsi->cdb[4]     = scb->sge.sys_buf_byte_count; /*Allocation length*/
                        scsi->cdb[5]     = 0;                           /*Control*/
                        scsi->cdb_len    = 6;
                        scsi->data_ptr   = scb->sge.sys_buf_addr;
                        scsi->data_len   = scb->sge.sys_buf_byte_count;
                        scsi->scsi_state = SCSI_STATE_SELECT;
                        scsi->scb_state  = 2;
                        return;

                    case CMD_SEND_OTHER_SCSI:
                        scsi->cdb_id = scsi->assign ? scsi->dev_id[scsi->scb_id].phys_id : scsi->present[scsi->scb_id];
                        dma_bm_read(scsi->scb_addr + 0x18, scsi->cdb, 12, 2);
                        spock_log("Send Other SCSI, SCB ID=%d, PHYS ID=%d, CDB[0]=%02x, CDB_ID=%d\n", scsi->scb_id, scsi->dev_id[scsi->scb_id].phys_id, scsi->cdb[0], scsi->cdb_id);
                        scsi->cdb[1]     = (scsi->cdb[1] & 0x1f) | (scsi->dev_id[scsi->scb_id].lun_id << 5); /*Patch correct LUN into command*/
                        scsi->cdb_len    = (scb->lba_addr & 0xff) ? (scb->lba_addr & 0xff) : 6;
                        scsi->scsi_state = SCSI_STATE_SELECT;
                        scsi->scb_state  = 2;
                        return;

                    case CMD_READ_DEVICE_CAPACITY:
                        scsi->cdb_id = scsi->assign ? scsi->dev_id[scsi->scb_id].phys_id : scsi->present[scsi->scb_id];
                        spock_log("Device Capacity, SCB ID=%d, PHYS ID=%d\n", scsi->scb_id, scsi->dev_id[scsi->scb_id].phys_id);
                        scsi->cdb[0]     = GPCMD_READ_CDROM_CAPACITY;
                        scsi->cdb[1]     = scsi->dev_id[scsi->scb_id].lun_id << 5; /*LUN*/
                        scsi->cdb[2]     = 0;                                      /*LBA*/
                        scsi->cdb[3]     = 0;
                        scsi->cdb[4]     = 0;
                        scsi->cdb[5]     = 0;
                        scsi->cdb[6]     = 0; /*Reserved*/
                        scsi->cdb[7]     = 0;
                        scsi->cdb[8]     = 0;
                        scsi->cdb[9]     = 0; /*Control*/
                        scsi->cdb_len    = 10;
                        scsi->scsi_state = SCSI_STATE_SELECT;
                        scsi->scb_state  = 2;
                        return;

                    case CMD_READ_DATA:
                        scsi->cdb_id = scsi->assign ? scsi->dev_id[scsi->scb_id].phys_id : scsi->present[scsi->scb_id];
                        spock_log("Device Read Data, SCB ID=%d, PHYS ID=%d\n", scsi->scb_id, scsi->dev_id[scsi->scb_id].phys_id);
                        scsi->cdb[0]     = GPCMD_READ_10;
                        scsi->cdb[1]     = scsi->dev_id[scsi->scb_id].lun_id << 5; /*LUN*/
                        scsi->cdb[2]     = (scb->lba_addr >> 24) & 0xff;           /*LBA*/
                        scsi->cdb[3]     = (scb->lba_addr >> 16) & 0xff;
                        scsi->cdb[4]     = (scb->lba_addr >> 8) & 0xff;
                        scsi->cdb[5]     = scb->lba_addr & 0xff;
                        scsi->cdb[6]     = 0; /*Reserved*/
                        scsi->cdb[7]     = (scb->block_count >> 8) & 0xff;
                        scsi->cdb[8]     = scb->block_count & 0xff;
                        scsi->cdb[9]     = 0; /*Control*/
                        scsi->cdb_len    = 10;
                        scsi->scsi_state = SCSI_STATE_SELECT;
                        scsi->scb_state  = 2;
                        return;

                    case CMD_WRITE_DATA:
                        scsi->cdb_id = scsi->assign ? scsi->dev_id[scsi->scb_id].phys_id : scsi->present[scsi->scb_id];
                        spock_log("Device Write Data\n");
                        scsi->cdb[0]     = GPCMD_WRITE_10;
                        scsi->cdb[1]     = scsi->dev_id[scsi->scb_id].lun_id << 5; /*LUN*/
                        scsi->cdb[2]     = (scb->lba_addr >> 24) & 0xff;           /*LBA*/
                        scsi->cdb[3]     = (scb->lba_addr >> 16) & 0xff;
                        scsi->cdb[4]     = (scb->lba_addr >> 8) & 0xff;
                        scsi->cdb[5]     = scb->lba_addr & 0xff;
                        scsi->cdb[6]     = 0; /*Reserved*/
                        scsi->cdb[7]     = (scb->block_count >> 8) & 0xff;
                        scsi->cdb[8]     = scb->block_count & 0xff;
                        scsi->cdb[9]     = 0; /*Control*/
                        scsi->cdb_len    = 10;
                        scsi->scsi_state = SCSI_STATE_SELECT;
                        scsi->scb_state  = 2;
                        return;

                    case CMD_VERIFY:
                        scsi->cdb_id = scsi->assign ? scsi->dev_id[scsi->scb_id].phys_id : scsi->present[scsi->scb_id];
                        spock_log("Device Verify\n");
                        scsi->cdb[0]     = GPCMD_VERIFY_10;
                        scsi->cdb[1]     = scsi->dev_id[scsi->scb_id].lun_id << 5; /*LUN*/
                        scsi->cdb[2]     = (scb->lba_addr >> 24) & 0xff;           /*LBA*/
                        scsi->cdb[3]     = (scb->lba_addr >> 16) & 0xff;
                        scsi->cdb[4]     = (scb->lba_addr >> 8) & 0xff;
                        scsi->cdb[5]     = scb->lba_addr & 0xff;
                        scsi->cdb[6]     = 0; /*Reserved*/
                        scsi->cdb[7]     = (scb->block_count >> 8) & 0xff;
                        scsi->cdb[8]     = scb->block_count & 0xff;
                        scsi->cdb[9]     = 0; /*Control*/
                        scsi->cdb_len    = 10;
                        scsi->data_len   = 0;
                        scsi->scsi_state = SCSI_STATE_SELECT;
                        scsi->scb_state  = 2;
                        return;

                    case CMD_REQUEST_SENSE:
                        scsi->cdb_id = scsi->assign ? scsi->dev_id[scsi->scb_id].phys_id : scsi->present[scsi->scb_id];
                        spock_log("Device Request Sense, ID=%d\n", scsi->cdb_id);
                        scsi->cdb[0]     = GPCMD_REQUEST_SENSE;
                        scsi->cdb[1]     = scsi->dev_id[scsi->scb_id].lun_id << 5; /*LUN*/
                        scsi->cdb[2]     = 0;
                        scsi->cdb[3]     = 0;
                        scsi->cdb[4]     = scb->sge.sys_buf_byte_count; /*Allocation length*/
                        scsi->cdb[5]     = 0;
                        scsi->cdb_len    = 6;
                        scsi->scsi_state = SCSI_STATE_SELECT;
                        scsi->scb_state  = 2;
                        return;

                    default:
                        break;
                }
                break;

            case 2: /* Wait */
                if (scsi->scsi_state == SCSI_STATE_IDLE) {
                    if (scsi_device_present(&scsi_devices[scsi->bus][scsi->cdb_id])) {
                        if (scsi->last_status == SCSI_STATUS_OK) {
                            scsi->scb_state = 3;
                            spock_log("Status is Good on device ID %d, cdb id = %d.\n", scsi->scb_id, scsi->cdb_id);
                        } else if (scsi->last_status == SCSI_STATUS_CHECK_CONDITION) {
                            uint16_t term_stat_block_addr7 = (0xc << 8) | 2;
                            uint16_t term_stat_block_addr8 = 0x20;
                            uint16_t term_stat_block_addrb = scsi->scb_addr & 0xffff;
                            uint16_t term_stat_block_addrc = scsi->scb_addr >> 16;

                            spock_set_irq(scsi, scsi->scb_id, IRQ_TYPE_COMMAND_FAIL);
                            scsi->scb_state = 0;
                            spock_log("Status Check Condition on device ID %d, cdb id = %d.\n", scsi->attention & 0x0f, scsi->cdb_id);
                            dma_bm_write(scb->term_status_block_addr + 0x7 * 2, (uint8_t *) &term_stat_block_addr7, 2, 2);
                            dma_bm_write(scb->term_status_block_addr + 0x8 * 2, (uint8_t *) &term_stat_block_addr8, 2, 2);
                            dma_bm_write(scb->term_status_block_addr + 0xb * 2, (uint8_t *) &term_stat_block_addrb, 2, 2);
                            dma_bm_write(scb->term_status_block_addr + 0xc * 2, (uint8_t *) &term_stat_block_addrc, 2, 2);
                        }
                    } else {
                        uint16_t term_stat_block_addr7 = (0xc << 8) | 2;
                        uint16_t term_stat_block_addr8 = 0x10;
                        spock_set_irq(scsi, scsi->scb_id, IRQ_TYPE_COMMAND_FAIL);
                        scsi->scb_state = 0;
                        spock_log("Status Check Condition on device ID %d on no device\n", scsi->scb_id);
                        dma_bm_write(scb->term_status_block_addr + 0x7 * 2, (uint8_t *) &term_stat_block_addr7, 2, 2);
                        dma_bm_write(scb->term_status_block_addr + 0x8 * 2, (uint8_t *) &term_stat_block_addr8, 2, 2);
                    }
                }
                break;

            case 3: /* Complete */
                if (scb->enable & 1) {
                    scsi->scb_state = 1;
                    scsi->scb_addr  = scb->scb_chain_addr;
                    spock_log("Next SCB - %08x\n", scsi->scb_addr);
                } else {
                    spock_set_irq(scsi, scsi->scb_id, IRQ_TYPE_SCB_COMPLETE);
                    scsi->scb_state = 0;
                    spock_log("Complete SCB ID = %d.\n", scsi->attention & 0x0f);
                }
                break;

            default:
                break;
        }
    } while (scsi->scb_state != old_scb_state);
}

static void
spock_process_scsi(spock_t *scsi, scb_t *scb)
{
    double         p;
    scsi_device_t *sd;

    switch (scsi->scsi_state) {
        case SCSI_STATE_IDLE:
            break;

        case SCSI_STATE_SELECT:
            spock_log("Selecting ID %d, SCB ID %d, LUN %d, adapter id = %d.\n", scsi->cdb_id, scsi->scb_id, scsi->dev_id[scsi->scb_id].lun_id, scsi->attention);
            if ((scsi->cdb_id != (uint8_t) -1) && scsi_device_present(&scsi_devices[scsi->bus][scsi->cdb_id])) {
                scsi->scsi_state = SCSI_STATE_SEND_COMMAND;
                spock_log("Device selected at ID %i.\n", scsi->cdb_id);
            } else {
                spock_log("Device selection failed at ID %i.\n", scsi->cdb_id);
                scsi->scsi_state = SCSI_STATE_IDLE;
                if (!scsi->cmd_timer) {
                    spock_log("Callback to reset\n");
                    scsi->cmd_timer = 1;
                }
                spock_add_to_period(scsi, 1);
            }
            break;

        case SCSI_STATE_SEND_COMMAND:
            sd = &scsi_devices[scsi->bus][scsi->cdb_id];
            memset(scsi->temp_cdb, 0x00, 12);

            if (scsi->cdb_len < 12) {
                memcpy(scsi->temp_cdb, scsi->cdb,
                       scsi->cdb_len);
                spock_add_to_period(scsi, scsi->cdb_len);
            } else {
                memcpy(scsi->temp_cdb, scsi->cdb,
                       12);
                spock_add_to_period(scsi, 12);
            }

            scsi->data_ptr = scb->sge.sys_buf_addr;
            scsi->data_len = scb->sge.sys_buf_byte_count;

            if (scb->enable & 0x400)
                sd->buffer_length = -1;
            else
                sd->buffer_length = spock_get_len(scsi, scb);

            scsi_device_command_phase0(sd, scsi->temp_cdb);
            spock_log("SCSI ID %i: Current CDB[0] = %02x, LUN = %i, data len = %i, max len = %i, phase val = %02x\n", scsi->cdb_id, scsi->temp_cdb[0], scsi->temp_cdb[1] >> 5, sd->buffer_length, spock_get_len(scsi, scb), sd->phase);

            if ((sd->phase != SCSI_PHASE_STATUS) && (sd->buffer_length > 0)) {
                p = scsi_device_get_callback(sd);
                if (p <= 0.0)
                    spock_add_to_period(scsi, sd->buffer_length);
                else
                    scsi->media_period += p;

                if (scb->enable & ENABLE_PT) {
                    int32_t  buflen = sd->buffer_length;
                    int      sg_pos = 0;
                    uint32_t DataTx = 0;
                    uint32_t Address;

                    if (scb->sge.sys_buf_byte_count > 0) {
                        for (uint32_t c = 0; c < scsi->data_len; c += 8) {
                            spock_rd_sge(scsi, scsi->data_ptr + c, &scb->sge);

                            Address = scb->sge.sys_buf_addr;
                            DataTx  = MIN((int) scb->sge.sys_buf_byte_count, buflen);

                            if ((sd->phase == SCSI_PHASE_DATA_IN) && DataTx) {
                                spock_log("Writing S/G segment %i: length %i, pointer %08X\n", c, DataTx, Address);
                                dma_bm_write(Address, &sd->sc->temp_buffer[sg_pos], DataTx, 2);
                            } else if ((sd->phase == SCSI_PHASE_DATA_OUT) && DataTx) {
                                spock_log("Reading S/G segment %i: length %i, pointer %08X\n", c, DataTx, Address);
                                dma_bm_read(Address, &sd->sc->temp_buffer[sg_pos], DataTx, 2);
                            }

                            sg_pos += scb->sge.sys_buf_byte_count;
                            buflen -= scb->sge.sys_buf_byte_count;

                            if (buflen < 0)
                                buflen = 0;
                        }
                    }
                } else {
                    spock_log("Normal Transfer\n");
                    if (sd->phase == SCSI_PHASE_DATA_IN) {
                        dma_bm_write(scsi->data_ptr, sd->sc->temp_buffer, MIN(sd->buffer_length, (int) scsi->data_len), 2);
                    } else if (sd->phase == SCSI_PHASE_DATA_OUT)
                        dma_bm_read(scsi->data_ptr, sd->sc->temp_buffer, MIN(sd->buffer_length, (int) scsi->data_len), 2);
                }

                scsi_device_command_phase1(sd);
            }
            scsi->last_status = sd->status;
            scsi->scsi_state  = SCSI_STATE_END_PHASE;
            break;

        case SCSI_STATE_END_PHASE:
            scsi->scsi_state = SCSI_STATE_IDLE;

            spock_log("State to idle, cmd timer %d\n", scsi->cmd_timer);
            if (!scsi->cmd_timer)
                scsi->cmd_timer = 1;

            spock_add_to_period(scsi, 1);
            break;
    }
}

static void
spock_callback(void *priv)
{
    double   period;
    spock_t *scsi = (spock_t *) priv;
    scb_t   *scb  = &scsi->scb;

    scsi->temp_period  = 0;
    scsi->media_period = 0.0;

    if (scsi->cmd_timer) {
        scsi->cmd_timer--;
        if (!scsi->cmd_timer) {
            spock_execute_cmd(scsi, scb);
        }
    }

    if (scsi->attention_wait && (scsi->scb_state == 0 || (scsi->attention_pending & 0xf0) == 0xe0)) {
        scsi->attention_wait--;
        if (!scsi->attention_wait) {
            scsi->attention = scsi->attention_pending;
            scsi->status &= ~STATUS_BUSY;
            scsi->cir[0]     = scsi->cir_pending[0];
            scsi->cir[1]     = scsi->cir_pending[1];
            scsi->cir[2]     = scsi->cir_pending[2];
            scsi->cir[3]     = scsi->cir_pending[3];
            scsi->cir_status = 0;

            spock_log("SCSI attention = %02x.\n", scsi->attention_pending);
            switch (scsi->attention >> 4) {
                case 1: /*Immediate command*/
                    scsi->cmd_status = 0x0a;
                    scsi->command    = scsi->cir[0] | (scsi->cir[1] << 8) | (scsi->cir[2] << 16) | (scsi->cir[3] << 24);
                    switch (scsi->command & CMD_MASK) {
                        case CMD_ASSIGN:
                        case CMD_DMA_PACING_CONTROL:
                        case CMD_FEATURE_CONTROL:
                        case CMD_INVALID_412:
                        case CMD_RESET:
                            spock_process_imm_cmd(scsi);
                            break;

                        default:
                            break;
                    }
                    break;

                case 3:
                case 4:
                case 0x0f: /*Start SCB*/
                    scsi->cmd_status = 1;
                    scsi->scb_addr   = scsi->cir[0] | (scsi->cir[1] << 8) | (scsi->cir[2] << 16) | (scsi->cir[3] << 24);
                    scsi->scb_id     = scsi->attention & 0x0f;
                    scsi->cmd_timer  = SPOCK_TIME * 2;
                    spock_log("Start SCB at ID = %d, attention = %02x\n", scsi->scb_id, scsi->attention >> 4);
                    scsi->scb_state = 1;
                    break;

                case 5:    /*Invalid*/
                case 0x0a: /*Invalid*/
                    scsi->in_invalid = 1;
                    scsi->cmd_timer  = SPOCK_TIME * 2;
                    break;

                case 0x0e: /*EOI*/
                    scsi->irq_status = 0;
                    spock_clear_irq(scsi, scsi->attention & 0x0f);
                    break;

                default:
                    break;
            }
        }
    }

    spock_process_scsi(scsi, scb);

    period = 0.2 * ((double) scsi->temp_period);
    timer_on_auto(&scsi->callback_timer, (scsi->media_period + period + 10.0));
    spock_log("Temporary period: %lf us (%" PRIi64 " periods), media period = %lf\n", scsi->callback_timer.period, scsi->temp_period, scsi->media_period);
}

static void
spock_mca_write(int port, uint8_t val, void *priv)
{
    spock_t *scsi = (spock_t *) priv;

    if (port < 0x102)
        return;

    io_removehandler((((scsi->pos_regs[2] >> 1) & 7) * 8) + 0x3540, 0x0008, spock_read, spock_readw, NULL, spock_write, spock_writew, NULL, scsi);
    mem_mapping_disable(&scsi->bios_rom.mapping);

    scsi->pos_regs[port & 7] = val;

    scsi->adapter_id = (scsi->pos_regs[3] & 0xe0) >> 5;

    if (scsi->pos_regs[2] & 1) {
        io_sethandler((((scsi->pos_regs[2] >> 1) & 7) * 8) + 0x3540, 0x0008, spock_read, spock_readw, NULL, spock_write, spock_writew, NULL, scsi);
        if ((scsi->pos_regs[2] & 0xf0) != 0xf0) {
            mem_mapping_set_addr(&scsi->bios_rom.mapping, ((scsi->pos_regs[2] >> 4) * 0x2000) + 0xc0000, 0x8000);
            mem_mapping_enable(&scsi->bios_rom.mapping);
        }
    }
    spock_log("[%04X:%08X]: POS Write Port = %x, val = %02x, rom addr = %05x\n", CS, cpu_state.pc, port & 7, val, ((scsi->pos_regs[2] >> 4) * 0x2000) + 0xc0000);
}

static uint8_t
spock_mca_read(int port, void *priv)
{
    const spock_t *scsi = (spock_t *) priv;

    spock_log("[%04X:%08X]: POS Read Port = %x, val = %02x\n", CS, cpu_state.pc,
            port & 7, scsi->pos_regs[port & 7]);
    return scsi->pos_regs[port & 7];
}

static uint8_t
spock_mca_feedb(void *priv)
{
    const spock_t *scsi = (spock_t *) priv;

    return (scsi->pos_regs[2] & 0x01);
}

static void
spock_mca_reset(void *priv)
{
    spock_t *scsi = (spock_t *) priv;

    scsi->in_reset       = 2;
    scsi->cmd_timer      = SPOCK_TIME * 50;
    scsi->status         = STATUS_BUSY;
    scsi->scsi_state     = SCSI_STATE_IDLE;
    scsi->scb_state      = 0;
    scsi->in_invalid     = 0;
    scsi->attention_wait = 0;
    scsi->basic_ctrl     = 0;

    /* Reset all devices on controller reset. */
    for (uint8_t i = 0; i < 8; i++) {
        scsi_device_reset(&scsi_devices[scsi->bus][i]);
        scsi->present[i] = 0;
    }

    spock_log("Reset.\n");
    mem_mapping_disable(&scsi->bios_rom.mapping);
    spock_mca_write(0x102, 0, scsi);
}

static void *
spock_init(const device_t *info)
{
    spock_t *scsi = malloc(sizeof(spock_t));
    memset(scsi, 0x00, sizeof(spock_t));

    scsi->bus = scsi_get_bus();

    scsi->irq = 14;

    scsi->bios_ver = device_get_config_int("bios_ver");
    scsi->spock_16bit = info->local & 0xff;

    switch (scsi->bios_ver) {
        case 0:
            rom_init_interleaved(&scsi->bios_rom, SPOCK_U68_1990_ROM, SPOCK_U69_1990_ROM,
                                 0xc8000, 0x8000, 0x7fff, 0x4000, MEM_MAPPING_EXTERNAL);
            break;
        case 1:
            rom_init_interleaved(&scsi->bios_rom, SPOCK_U68_1991_ROM, SPOCK_U69_1991_ROM,
                                 0xc8000, 0x8000, 0x7fff, 0x4000, MEM_MAPPING_EXTERNAL);
            break;

        default:
            break;
    }
    mem_mapping_disable(&scsi->bios_rom.mapping);

    scsi->pos_regs[0] = scsi->spock_16bit ? 0xfe : 0xff;
    scsi->pos_regs[1] = 0x8e;
    mca_add(spock_mca_read, spock_mca_write, spock_mca_feedb, spock_mca_reset, scsi);

    scsi->in_reset  = 2;
    scsi->cmd_timer = SPOCK_TIME * 50;
    scsi->status    = STATUS_BUSY;

    for (uint8_t c = 0; c < (SCSI_ID_MAX - 1); c++)
        scsi->dev_id[c].phys_id = -1;

    scsi->dev_id[SCSI_ID_MAX - 1].phys_id = scsi->adapter_id;

    timer_add(&scsi->callback_timer, spock_callback, scsi, 1);
    scsi->callback_timer.period = 10.0;

    timer_set_delay_u64(&scsi->callback_timer,
                        (uint64_t) (scsi->callback_timer.period * ((double) TIMER_USEC)));

    scsi_bus_set_speed(scsi->bus, 5000000.0);

    return scsi;
}

static void
spock_close(void *priv)
{
    spock_t *scsi = (spock_t *) priv;

    if (scsi) {
        free(scsi);
        scsi = NULL;
    }
}

static int
spock_available(void)
{
    return rom_present(SPOCK_U68_1991_ROM) && rom_present(SPOCK_U69_1991_ROM) && rom_present(SPOCK_U68_1990_ROM) && rom_present(SPOCK_U69_1990_ROM);
}

static const device_config_t spock_rom_config[] = {
  // clang-format off
    {
        .name = "bios_ver",
        .description = "BIOS Version",
        .type = CONFIG_SELECTION,
        .default_string = "",
        .default_int = 1,
        .file_filter = "",
        .spinner = { 0 },
        .selection = {
            { .description = "1991 BIOS (>1GB)", .value = 1 },
            { .description = "1990 BIOS",        .value = 0 },
            { .description = ""                             }
        },
    },
    { .name = "", .description = "", .type = CONFIG_END }
  // clang-format on
};

const device_t spock_device = {
    .name          = "IBM PS/2 SCSI Adapter (Spock)",
    .internal_name = "spock",
    .flags         = DEVICE_MCA,
    .local         = 0,
    .init          = spock_init,
    .close         = spock_close,
    .reset         = NULL,
    { .available = spock_available },
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = spock_rom_config
};

const device_t tribble_device = {
    .name          = "IBM PS/2 SCSI Adapter (Tribble)",
    .internal_name = "tribble",
    .flags         = DEVICE_MCA,
    .local         = 1,
    .init          = spock_init,
    .close         = spock_close,
    .reset         = NULL,
    { .available = spock_available },
    .speed_changed = NULL,
    .force_redraw  = NULL,
    .config        = spock_rom_config
};
